A polarization apparatus includes a conductive carrier, a dielectric barrier discharge (DBD) plasma source, an electric net, a DBD power supply, and a DC power supply. The conductive carrier has a carrying surface which is configured to carry a work piece. The work piece includes a piezoelectric material film, and the conductive carrier is grounded. The DBD plasma source is disposed over the carrying surface and is configured to apply plasma toward the piezoelectric material film. The electric net is disposed between the carrying surface and the DBD plasma source. The DBD power supply includes a first electrode and a second electrode, in which the first electrode is electrically connected to the DBD plasma source, and the second electrode is grounded. The DC power supply includes a third electrode and a fourth electrode. The third electrode is electrically connected to the electric net, and the fourth electrode is grounded.

The disclosure relates to a flexible active species generator comprising: a first electrode of a conductive metal thin film; a second electrode of a ground electrode; a flexible dielectric layer of an insulator formed between the first electrode and the second electrode; and a plasma resistant functional layer formed between the dielectric layer and the second electrode, wherein the first electrode and the second electrode are electrically connected to an external power supply to generate an atmospheric pressure plasma to generate active species. The flexible active species generator has a plasma resistant function to prevent deformation and decomposition of an insulator caused by the plasma as well as an active species generating function from atmospheric pressure plasma, and has durability and safety, which is thus applicable to articles, foods, garments and human body in various forms.

Described herein are apparatus and methods of printing in the presence of plasma. The apparatus includes a modular print head comprising an inlet module, a plasma module with movable electrode configurations, and a nozzle module. The modular design of the print head allows for printing on and treatment of surfaces in many different applications.

A small and inexpensive plasma actuator is capable of accelerating induced flow and increasing the effect of controlling flow. A plurality of electrode pairs are disposed on a dielectric layer upstream to downstream along a predetermined direction. Each electrode pair includes an upstream electrode disposed on one surface of the dielectric layer and a downstream electrode disposed on another surface of the dielectric layer to sandwich the dielectric layer between the upstream electrode. A lowest electrode is on the one surface of the dielectric layer displaced downstream from the downstream electrode in an the most downstream electrode pair to have the same potential as the downstream electrode. A voltage application device is configured to apply voltage including AC voltage or repeated pulse voltage to each electrode pair such that the potential of the applied voltage inverts at adjacent electrode pairs.

A blower having high efficiency and low noise by actively controlling airflow in the blower, and an air conditioner having the blower is provided. The air conditioner has a blower. The blower includes a fan having a hub and at least one blade provided on an outer circumferential surface of the hub, a motor to rotatably drive the hub, a shroud configured to surround the periphery of the fan and at least one actuator installed in the shroud and configured to form an airflow along an inner circumferential surface of the shroud.

An apparatus configured to reduce drag is provided. The apparatus includes a plasma actuator including a hollow cylinder with two open bases, a first electrode disposed inside the cylinder, a second electrode disposed outside the cylinder, and a plasma layer disposed inside the cylinder next to the first electrode, a surface including the plasma actuator disposed on the surface, and a motion actuator configured to move the plasma actuator in a sweeping motion across a face of the surface.

Described herein are apparatus and methods of printing in the presence of plasma. The apparatus includes a modular print head comprising an inlet module, a plasma module with movable electrode configurations, and a nozzle module. The modular design of the print head allows for printing on and treatment of surfaces in many different applications.

Described herein are apparatus and methods of printing in the presence of plasma. The apparatus includes a modular print head comprising an inlet module, a plasma module with movable electrode configurations, and a nozzle module. The modular design of the print head allows for printing on and treatment of surfaces in many different applications.

A plasma treatment unit having a high-voltage stage (5, 6), arranged in a housing, for generating high-voltage signals suitable for the generation of a plasma, and having a head part (2) which is connectable to the high-voltage stage (5, 6) and in which there is situated an electrode arrangement (13) shielded by a dielectric (9), is suitable for plasma treatments in particular in the body interior by virtue of the fact that the head part (2) has an elongate transition piece (10) which is attachable to the housing and on that end of which which is not connectable to the housing there is arranged a treatment head (16, 16), the dimensions of which perpendicular to the longitudinal direction of the transition piece (10) greatly exceed the dimensions of the transition piece (10), and that, in the treatment head (16, 16), the electrode arrangement (13) forms a spatially closed flexible sheath (12) around a resiliently elastic core (14) and is covered at its outer lateral surface by a thin layer (15) of the flexible dielectric (9), such that the treatment head (16, 16) can, as it is inserted into a body interior, assume the shape of the surrounding tissue in the body interior.

A plasma generating apparatus includes a dielectric medium with electrodes on first and second sides of the dielectric medium. A power source creates a voltage differential between the electrodes on the first side and the electrodes on the second side of the dielectric medium. Plasma is generated on both of the first and second sides of the dielectric medium as a result of the voltage differential.